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I'm writing a tree-like container, where each "node" has a list with branches/subtrees, currently my head looks like:

class _tree {
    typedef _tree* tree_ptr;
    typedef std::list<_tree> _subTreeTy;

    explicit _tree(const _ValTy& v, const _NameTy& n); //create a new tree
    _tree(const _ValTy& v, const _NameTy& n, tree_ptr _root); 
         //create a new tree and add it as branch to "_root".


    void add_branch(const _tree& branch); //add by copy
    void add_branch(_tree&& branch); //add by move
    _subTreeTy subtrees;
    _ValTy value;
    _NameTy name;

_tree::_tree(const _ValTy& v, const _NameTy& n, tree_ptr _root)
    : root(_root),
    _root->add_branch(*this); //not rvalue(???)

Now the second constructor would create a tree inside _root - however how does this work with calling (ignore private violation):

_tree Base(0,"base");
_tree Branch(1, "branch", &Base);
Base.subtrees.begin()->value = 8;
std::cout << Branch.value;

How would I make it so that Branch & *Base.subtrees.begin() refer to the same node? Or should i go the other way. Use add_branch() to CREATE a branch/subtree?

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Identifiers that start with underscore followed by an upper-case letter are reserved for the implementation. And look ugly. – Cat Plus Plus Oct 9 '11 at 12:18
What does it have to do with move semantics? – crazyjul Oct 9 '11 at 13:10
I took the liberty of changing the title a bit as it wasn't very informative (also other minor changes). Hopefully this still conveys what your question is about. – Luc Danton Oct 9 '11 at 14:10
up vote 3 down vote accepted

Move semantics is about moving the internals of an object, not the object (as a typed piece of memory) itself. It's best to think about it in terms of values and invariants, since C++ still has value semantics even when moving is taken into account. This means:

std::unique_ptr<int> first(new int);
// invariant: '*this is either null or pointing to an object'
// current value: first is pointing to some int
assert( first != nullptr );

// move construct from first
std::unique_ptr<int> second(std::move(first));

// first and second are separate objects!
assert( &first != &second );

// New values, invariants still in place
assert( first == nullptr );
assert( second != nullptr );

// this doesn't affect first since it's a separate object
second.reset(new int);

In other words, while you can convert the expression *this to an rvalue by doing std::move(*this) what you want cannot be achieved right now since std::list<_tree> uses value semantics and _tree has value semantics itself. *Base.subtrees.begin() is a distinct object from Branch and as things are modifications to the former won't affect the latter.

Switch to reference semantics if that's what you want (or need), for instance by using std::shared_ptr<_tree> and std::enable_shared_from_this (you'd then use _root->add_branch(shared_from_this()) inside the constructor). I wouldn't recommend it though, this could get messy. Value semantics are very desirable in my opinion.

With value semantics, using your tree could look like:

_tree Base(0, "base");
auto& Branch = Base.addBranch(1, "branch");

That is, addBranch returns a reference to the newly constructed node. Sprinkling some move semantics on top:

_tree Base(0, "base");
_tree Tree(1, "branch); // construct a node not connected to Base
auto& Branch = Base.addBranch(std::move(Tree));
// The node we used to construct the branch is a separate object
assert( &Tree != &Branch );

Strictly speaking if _tree is copyable move semantics are not necessary though, Base.addBranch(Tree); would work too.

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